Air seperation process - Patent 1271081

(19)

(11)

EP 1 271 081 A2

(12)	EUROPEAN PATENT APPLICATION

(43)	Date of publication:
	02.01.2003 Bulletin 2003/01

(21)	Application number: 02254046.2

(22)	Date of filing: 11.06.2002

(51)	International Patent Classification (IPC)⁷: F25J 3/04

(84)	Designated Contracting States:
	AT BE CH CY DE DK ES FI FR GB GR IE IT LI LU MC NL PT SE TR
	Designated Extension States:
	AL LT LV MK RO SI

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Priority:

12.06.2001 US 879232

(71)	Applicant: AIR PRODUCTS AND CHEMICALS, INC.
	Allentown, PA 18195-1501 (US)

(72)	Inventors:
	Griffiths, John Louis Pittsburgh, PA 15232 (US) Higginbotham, Paul Guildford, Surrey GU1 3QG (GB)

(74)	Representative: Burford, Anthony Frederick
	W.H. Beck, Greener & Co. 7 Stone Buildings Lincoln's Inn London WC2A 3SZ London WC2A 3SZ (GB)

(54)	Air seperation process

(57) Nitrogen (107 & 155) is produced by the cryogenic distillation of air, or other multicomponent fluid containing nitrogen and oxygen, (101) using a distillation column system having a supplemental column (149) and a distillation unit including a lower-pressure column (121) and a higher-pressure column (103). The pressure in the supplemental column (149) is at least equal to the pressure of the lower-pressure column (121). A liquid stream (123) enriched in oxygen is withdrawn from the lower-pressure column (121) and is vaporized through indirect latent heat transfer (129), thereby producing a reflux stream (137), a portion of which is sent to the lower-pressure column (121), the higher-pressure column (103), and/or the supplemental column (149). At least a portion (147) of the reflux for the supplemental column (149) is derived from the distillation unit. A nitrogen-enriched liquid (141) removed from the distillation unit is increased in pressure (145) and is fed to the supplemental column (149) or back to the distillation unit. Additionally or alternatively, the nitrogen-enriched liquid (119,141) is increased or reduced in pressure and fed to the supplemental column (149). An oxygen-enriched fluid (153) from the bottom of the supplemental column (149) is fed to the distillation unit. At least some of the nitrogen overhead (155) from the supplemental column is recovered as product.

Description

[0001] The present invention relates generally to processes for the cryogenic distillation of air, and in particular to such processes used to produce at least a nitrogen product.

[0002] There are numerous processes which relate to the production of at least a nitrogen product by cryogenic air separation. Frequently these processes have a double column distillation unit, which utilizes a higher-pressure column and a lower-pressure column. Typically, though not exclusively, the higher-pressure column obtains a portion of its reflux through the use of a reboiler-condenser. Herein a vapor in the higher-pressure column is condensed through indirect latent heat transfer with a liquid in the lower-pressure column. Air is primarily fed to the higher-pressure column, but occasionally also may be introduced to the lower-pressure column. Meanwhile, products may be removed from either column.

[0003] Many of these processes are concerned with once through separation, wherein all fluids flow from higher pressures to lower pressures. Typically, the highest-pressure stream in once through separation cycles is a compressed air stream. These once through cycles produce products from the distillation unit at pressures no greater than that of the higher-pressure column. Post-separation compression allows for the production of products at pressures other than those found in the cryogenic air separation process. Two such embodiments of post-separation compression are found in pumped LOX cycles and pumped LIN cycles. In these embodiments a liquid product is removed from the distillation unit, pumped to an elevated pressure, and delivered to a warm elevated pressure product.

[0004] In JP-A-1062062, US-A-5,906,113 (Lynch et al.), US-A-4,582,518 (Erickson) and US-A-5,918,482 (Potempa), liquid nitrogen is removed from a single column cycle and provides a portion of the reflux for an additional column.

[0005] A second set of cycles exist wherein a liquid stream is removed from the lower-pressure column and its pressure increased, for example through pumping. This elevated pressure stream is returned to the cryogenic air separation cycle. These cycles may be described as pump-back cycles, and do not pertain to the set of once through cycles.

[0006] An advantage of a pump-back cycle is that products may be produced at pressures greater than that of the lower-pressure column. These cycles are especially beneficial if a single, high pressure product is required. However, the pressure of the product stream is still bounded by the pressures found in the higher and lower-pressure columns.

[0007] In US-A-5,964,104 (Rottmann) liquid nitrogen from the lower-pressure column of a double column cycle is pumped to the higher-pressure column where it is used as reflux. In WO-A-98/19122 (Corduan) liquid nitrogen from the lower-pressure column of a double column cycle is pumped to a heat exchanger where it is either fully or partially vaporized. A portion of the reflux for the higher-pressure column is provided by indirect condensation with this boiling pumped liquid nitrogen. These cycles just described do not contain additional columns.

[0008] A third set of cycles exists where an additional or supplemental column is used. These supplemental columns are known in the prior art as Intermediate Pressure Columns (IP), or Medium Pressure Columns (MP). Most of these cycles improve the once through cycles by removing a product at a pressure between that of the higher-pressure column and the lower-pressure column. A typical method of operation is when a stream of liquid is removed from the higher-pressure column to reflux the supplemental column. This removal of higher-pressure reflux tends to reduce the production of nitrogen product from the higher-pressure column. The pressure of the nitrogen product from this supplemental column remains bounded between the higher and lower-pressure columns.

[0009] In US-A-5,069,699 (Agrawal) air is sent to the higher-pressure column of a double column cycle and an extra high pressure (EHP) column. A gaseous nitrogen stream from the EHP column is condensed indirectly with an oxygen enriched liquid in the lower-pressure column. A portion of this condensed EHP gaseous nitrogen stream is used as reflux for the high-pressure (HP) column. In EP-A-0921367 and EP-A-0924486 liquid nitrogen produced in the third column, at a pressure typically around 90 psia (620 kPa), may be used as reflux for both the higher-pressure and lower-pressure columns. In all of these cycles no portion of the nitrogen product is removed from the additional column.

[0010] In US-A-3,688,513 (Streich, et al.) liquid nitrogen from the lower-pressure column of a double column cycle is pumped and used as a portion of the reflux for an IP column. A product of enriched oxygen is removed from the bottom of the IP column. In this cycle an oxygen enriched liquid from the bottom of the IP column is not sent to the distillation unit.

[0011] In US-A-4,533,375 (Erickson) and US-A-4,605,427 (Erickson) the lower-pressure column is refluxed through the vaporization of liquid nitrogen. In these cases just described, the vaporizing liquid has an oxygen concentration less than that of air.

[0012] In US-A-5,730,004 (Voit) and US-A-4,254,629 (Olszewski) air is sent to an IP column. Reflux for this IP column is provided by condensing nitrogen indirectly against a boiling oxygen enriched liquid. A portion of the condensed IP nitrogen liquid is used as reflux to the lower-pressure column of a double column cycle. In US-A-5,485,729 (Higginbotham) an IP column derives reflux by condensing gaseous nitrogen in intermediate reboiler condensers located within a lower-pressure column of a double column cycle. A portion of the liquid nitrogen produced is used to reflux the lower-pressure column. In US-A-5,402,647 (Bonaquist, et al.) a third column, operating at a pressure generally between 30 psia (200 kPa) and 60 psia (400 kPa), produces a liquid nitrogen product, which is pumped to the higher-pressure column where it is used as reflux. In these cases, no liquid from the distillation unit is raised in pressure and sent to either the additional column or returned to the distillation unit.

[0013] In EP-A-1043558 (Brugerolle) liquid nitrogen is pumped from a distillation unit to a power producing cycle. Herein, an oxygen-enriched fluid is recovered and returned to the distillation unit. The nitrogen-enriched gas produced from the top of the column is injected into a gas turbine ensuring that the mass flowrate to the expander is not compromised. This reference describes the increase of production of oxygen from the distillation unit and also describes cycles known in the prior art as oxygen plants. A liquid stream is therefore not removed from the lower-pressure column and vaporized in such a manner that a reflux stream is produced.

[0014] It is desired to have an improved air separation process for the production of nitrogen.

[0015] It is further desired to have an improved air separation process for the production of nitrogen which overcomes the difficulties and disadvantages of the prior art processes to provide better and more advantageous results.

[0016] According to one aspect, the present invention provides a process for separating a multi-component fluid comprising oxygen and nitrogen to produce nitrogen, said process using a distillation column system having at least three distillation columns, including a higher-pressure column operating at a first pressure, a lower-pressure column operating at a second pressure lower than the first pressure, and a supplemental column operating at a third pressure greater than or equal to the second pressure, optionally wherein the higher-pressure column and the lower-pressure column are thermally linked through a first heat exchanger, comprising:

feeding a first stream of the multi-component fluid to the higher-pressure column;

feeding a second stream of the multi-component fluid or another multi-component fluid compromising oxygen and nitrogen to the supplemental column;

withdrawing a first nitrogen-rich vapor stream from the higher-pressure column or the lower-pressure column;

withdrawing a first oxygen-rich liquid stream from the lower-pressure column;

heat exchanging at least a portion of the first oxygen-rich liquid stream indirectly against at least a portion of the first nitrogen-rich vapor stream in the first heat exchanger or a second heat exchanger, thereby at least partially vaporizing the first oxygen-rich liquid stream and at least partially condensing the first nitrogen-rich vapor stream;

changing the pressure of at least a portion of the condensed first nitrogen-rich vapor stream;

feeding at least a portion of the condensed first nitrogen-rich vapor stream to the higher pressure column, lower pressure column or supplemental column;

withdrawing a second oxygen-rich liquid stream from the supplemental column;

feeding at least a portion of the second oxygen-rich liquid stream to the lower-pressure column or the higher-pressure column; and

withdrawing a first stream of nitrogen product from the supplemental column, and

wherein at least a portion of the reflux for the supplemental column is provided by the condensed first nitrogen-rich vapor stream or is otherwise derived from the higher pressure or lower pressure column.

[0017] In a preferred embodiment, the invention provides a process for the cryogenic distillation of multi-component fluid comprising oxygen and nitrogen, especially air, within a distillation column system that contains at least a distillation unit and a supplemental column. The distillation unit comprises at least a lower-pressure column and a higher-pressure column and the pressure of the supplemental column is at least equal to the pressure of the lower-pressure column and may be greater than the pressure of the higher-pressure column. A liquid stream enriched in oxygen is withdrawn from the lower-pressure column. This liquid is vaporized through indirect latent heat transfer to produce a reflux stream, a portion of which is sent to the lower-pressure column, the higher-pressure column, and/or the supplemental column. At least a portion of the reflux for the supplemental column is derived from the distillation unit. A nitrogen enriched liquid removed from the distillation unit is raised in pressure and is sent to either the supplemental column or back to the distillation unit. An oxygen-enriched fluid from the bottom of the supplemental column is sent to the distillation unit. At least a portion of the nitrogen product is removed from the supplemental column.

[0018] Another aspect of the invention provides a process for separating a multi-component fluid comprising oxygen and nitrogen, especially air, to produce nitrogen. The process uses a distillation column system having at least three distillation columns, including a higher-pressure column operating at a first pressure, a lower-pressure column operating at a second pressure lower than the first pressure, and a supplemental column operating at a third pressure greater than or equal to the second pressure. The higher-pressure column and the lower-pressure column usually are thermally linked through a first heat exchanger. A first stream of the multi-component fluid is fed to the higher-pressure column and a second stream of the multi-component fluid or another multi-component fluid comprising oxygen and nitrogen is fed to the supplemental column. A first nitrogen-rich vapor stream is withdrawn from the higher-pressure column or the lower-pressure column and a first oxygen-rich liquid stream is withdrawn from the lower-pressure column. At least a portion of the first oxygen-rich liquid stream is heated indirectly against at least a portion of the first nitrogen-rich vapor stream in the first heat exchanger or a second heat exchanger, thereby at least partially vaporizing the first oxygen-rich liquid stream and at least partially condensing the first nitrogen-rich vapor stream. The pressure of at least a portion of the condensed first nitrogen-rich vapor stream is changed and at least a portion of the condensed first nitrogen-rich vapor stream is fed to the supplemental column. A second oxygen-rich liquid stream is withdrawn from the supplemental column and at least a portion of the second oxygen-rich liquid stream is fed to the lower-pressure column or the higher-pressure column. A first stream of nitrogen product is withdrawn from the supplemental column.

[0019] A stream of a product enriched in oxygen can be withdrawn from the lower-pressure column.

[0020] A stream of product enriched in nitrogen can be withdrawn from the higher-pressure column.

[0021] The third pressure can be greater than or equal to the first pressure.

[0022] A first nitrogen-rich liquid stream from the first heat exchanger can be fed to the lower-pressure column at a first location, and a second nitrogen-rich liquid stream from the second heat exchanger can be fed to the lower-pressure column at a second location above the first location.

[0023] The pressure of the portion of the condensed nitrogen-rich vapor stream can be changed by reducing the pressure. A second nitrogen-rich vapor stream can be withdrawn from the lower-pressure column; a third oxygen-rich liquid stream withdrawn from the lower-pressure column; at least a portion of the third oxygen-rich liquid stream heat exchanged indirectly against at least a portion of the second nitrogen-rich vapor stream in a second heat exchanger, thereby at least partially condensing the second nitrogen-rich vapor stream; the pressure of at least a portion of the condensed nitrogen-rich vapor stream increased; and at least a portion of the condensed second nitrogen-rich vapor stream fed to the higher-pressure column.

[0024] The pressure of the portion of the condensed first nitrogen-rich vapor stream can be changed by increasing the pressure. A second nitrogen-rich vapor stream can be withdrawn from the supplemental column; a third oxygen-rich liquid stream withdrawn from the lower-pressure column; at least a portion of the third oxygen-rich liquid stream heat exchanged indirectly against at least a portion of the second nitrogen-rich vapor stream in a third heat exchanger, thereby at least partially condensing the second nitrogen-rich vapor stream; and at least a portion of the condensed second nitrogen-rich vapor stream fed to the supplemental column. A portion of the condensed first nitrogen-rich vapor stream can be fed to the supplemental column at a first location, and a portion of the condensed second nitrogen-vapor stream fed to the supplemental column at the first location or at a second location above the first location.

[0025] Another aspect of the present invention is an apparatus, especially a cryogenic air separation unit, for separating a multi-component fluid comprising oxygen and nitrogen to produce nitrogen using a process of the present invention , said apparatus comprising:

a distillation column system having at least three distillation columns, including:

a higher-pressure column for operating at a first pressure,

a lower-pressure column for operating at a second pressure lower than the first pressure,

a supplemental column for operating at a third pressure greater than or equal to the second pressure, and

a first heat exchanger for thermally linking the higher-pressure column and the lower-pressure column:

conduit means for feeding a first stream of the multi-component fluid to the higher-pressure column;

conduit means for feeding a second stream of the multi-component fluid or another multi-component fluid compromising oxygen and nitrogen to the supplemental column;

conduit means for withdrawing a first nitrogen-rich vapor stream from the higher-pressure column or the lower-pressure column;

conduit means for withdrawing a first oxygen-rich liquid stream from the lower-pressure column;

optionally, a second heat exchanger for heat exchanging at least a portion of the first oxygen-rich liquid stream indirectly against at least a portion of the first nitrogen-rich vapor stream;

pressure changing means for changing the pressure of at least a portion of a condensed first nitrogen-rich vapor stream from the first or second heat exchanger;

conduit means for feeding at least a portion of the condensed first nitrogen-rich vapor stream to the supplemental column;

conduit means for withdrawing a second oxygen-rich liquid stream from the supplemental column and feeding at least a portion of the second oxygen-rich liquid stream to the lower-pressure column or the higher-pressure column; and

conduit means for withdrawing a first stream of nitrogen product from the supplemental column.

[0026] In another aspect, the present invention provides an apparatus, especially a cryogenic air separation unit, for the preparation of a nitrogen product by cryogenic distillation of multi-component fluid comprising oxygen and nitrogen by a process of the invention, said apparatus comprising:

a distillation column system that contains at least a distillation unit, which comprises at least a lower-pressure column and a higher-pressure column, and a supplemental column for operating at a pressure is at least equal to the pressure of the lower-pressure column;

conduit means for withdrawing a liquid stream enriched in oxygen from the lower-pressure column;

a heat exchanger for vaporizing the oxygen-enriched liquid stream through indirect latent heat transfer with a nitrogen-enriched vapor stream to produce a reflux stream;

conduit means for sending a portion of the reflux stream to the lower-pressure column, the higher-pressure column, and/or the supplemental column;

at least when said conduit means does not send a portion of said reflux stream to the supplemental column, reflux means for providing a portion of the reflux for the supplemental column from the distillation unit;

pressure-increasing means for raising the pressure of a nitrogen enriched liquid removed from the distillation unit;

conduit means for sending said pressure-increased stream to the supplemental column or to the distillation unit;

conduit means for sending an oxygen-enriched fluid from the bottom of the supplemental column to the distillation unit; and

conduit means for removing as product at least a portion of the nitrogen product from the supplemental column.

[0027] The invention will be described by way of example with reference to the accompanying drawings, in which:

Figure 1 is a schematic diagram of one embodiment of the present invention;

Figure 2 is a schematic diagram of a second embodiment of the present invention;

Figure 3 is a schematic diagram of a third embodiment of the present invention;

Figure 4 is a schematic diagram of a fourth embodiment of the present invention;

Figure 5 is a schematic diagram of a fifth embodiment of the present invention;

Figure 6 is a schematic diagram of a sixth embodiment of the present invention; and

Figure 7 is a schematic diagram of a prior art distillation column system.

[0028] Figure 1 shows an embodiment of the invention wherein liquid streams (141, 119) from both the lower-pressure column 121 and the higher-pressure column 103 combine to form a primary reflux stream 143 to reflux the supplemental column 149. The primary reflux stream is increased in pressure by a pump 145 before being fed to the supplemental column as supplemental column reflux stream 147.

[0029] Air component vapor stream 101, at a pressure typically between 80 psia (550 kPa) and 300 psia (2100 kPa), is fed to the higher-pressure column 103 wherein this stream is separated through cryogenic distillation into stream 105 (oxygen-rich) and stream 107 (nitrogen-rich). Stream 107 is divided into stream 109 and stream 111. Stream 111 is condensed indirectly in a first heat exchanger 113 against liquid in the bottom of the lower-pressure column 121, thereby producing stream 115, which stream is separated into stream 117 and stream 119. Stream 117 is returned to the higher-pressure column 103. Stream 105 is reduced in pressure and sent to the lower-pressure column wherein this stream is separated by cryogenic distillation into stream 123 and stream 125. Stream 123, a portion of the liquid from the bottom of the lower-pressure column, is reduced in pressure and sent as stream 127 to a second heat exchanger 129, wherein the liquid is vaporized by indirect latent heat transfer, thereby producing waste stream 131. Stream 125 is divided into product stream 133 (nitrogen) and stream 135. Stream 135 is sent to the second heat exchanger 129 and is condensed by indirect latent heat transfer with stream 127, thereby producing stream 137. Stream 137 is divided into stream 139 and stream 141. Stream 139 is returned to the lower-pressure column 121. As mentioned above, stream 141 is mixed with stream 119 to produce the primary reflux stream 143, which is increased in pressure by pump 145 to become the supplemental column reflux stream 147, which is fed to the supplemental column 149. Secondary air component vapor stream 151 is fed to the supplemental column wherein this stream is separated by cryogenic distillation into stream 153 and primary nitrogen product stream 155. Stream 153 is reduced in pressure and sent to the lower-pressure column 121.

[0030] Figure 2 is an embodiment of the invention wherein reflux for the supplemental column 149 is derived from the higher-pressure column 103 only. Stream 201, a further portion of stream 107, is condensed in the second heat exchanger 129 through indirect latent heat transfer, thereby producing stream 203. Stream 203 is mixed with stream 115 from the first heat exchanger 113, thereby producing stream 117 and stream 119. Stream 139, now a portion of stream 119, is sent to the lower-pressure column 121. Stream 143, a further portion of stream 119, is increased in pressure in pump 145 and sent to the supplemental column 149 as supplemental column reflux stream 147.

[0031] Figure 3 is an embodiment of the invention wherein reflux for the supplemental column 149 is derived from only the lower-pressure column 121. Stream 135 is condensed through indirect latent heat transfer in the second heat exchanger 129, thereby producing stream 301. Stream 301 is increased in pressure in pump 145 and sent as supplemental column reflux stream 147 to the supplemental column 149.

[0032] Figure 4 is an embodiment of the invention wherein a portion of the reflux for the supplemental column 149 is derived from the lower-pressure column 121 and a further portion of the reflux is derived from the supplemental column 149. Stream 127 is divided into stream 409 and stream 411. Stream 409 is vaporized through indirect latent heat transfer in the second heat exchanger 129, thereby producing stream 131. Stream 411 is vaporized through latent heat transfer in a third heat exchanger 405, thereby producing stream 413, which is returned to the lower-pressure column 121. Stream 401 is removed from the top of the supplemental column 149 and is divided into primary nitrogen product stream 155 and stream 403. Stream 403 is condensed through indirect latent heat transfer in the third heat exchanger 405, thereby producing stream 407. Stream 407 is returned to the supplemental column 149 wherein it is used as reflux. It is preferable, though not necessary, that the feed position of stream 407 into the supplemental column 149 be no lower than the feed position of the supplemental column reflux stream 147.

[0033] Figure 5 is an embodiment of the invention wherein a supplemental column reflux stream 147 solely from the higher-pressure column 103 refluxes the supplemental column 149 and a liquid stream 501 is pumped to the higher-pressure column 103 from pump 145. Stream 141 is raised in pressure in the pump and is sent to the higher-pressure column as liquid stream 501. Stream 119 is reduced in pressure and is sent to the supplemental column as supplemental column reflux stream 147.

[0034] Figure 6 is an embodiment of the invention wherein the supplemental column 149 is refluxed solely from the lower-pressure column 121. Stream 153 is reduced in pressure and is sent to the higher-pressure column 103 as stream 601. Stream 119 is reduced in pressure and is sent to the lower-pressure column 121 as stream 603. Stream 603 is introduced into the lower-pressure column 121 at a feed position in that column below the feed position of stream 139. Stream 141 is increased in pressure in pump 145 and is sent to the supplemental column 149 as supplemental column reflux stream 147.

[0035] In the embodiments of Figures 1, 4, 5 and 6, the pressure of the supplemental column (149) can be less than, equal to or greater than the pressure in the higher pressure column (103).

[0036] Figure 7 shows a prior art pump-back cycle similar to that disclosed in US-A-5,964,104 (Rottmann).

[0037] Numerous modifications or additions may be applied to the embodiments shown in Figures 1-6. For example, the above discussion has centered around a process producing at least a nitrogen product. This nitrogen product has been shown as various streams, 109, 133, and 155. It will be apparent to persons skilled in the art that the invention may be applied where additional nitrogen streams at other purities and/or pressures may be required, necessitating the use of further columns. Additionally, the invention may be applied to a process where a single nitrogen product is required. An important feature of the invention is that a portion of the nitrogen product is removed from the supplemental column 149.

[0038] In the discussion above, the nitrogen product streams 109, 133, and 155 each have been described as having a pressure equal to that of the corresponding column for the stream. However, the pressures of these streams may be changed before being delivered as product. Examples include but are not limited to: 1) pressure increased in a compressor, 2) pressure decreased in an expander, 3) pressure decreased in a throttling device, and 4) pressure decreased in a turboejector.

[0039] Refrigeration for the process has not been illustrated in the examples given, as this is not required to describe the essence of the invention. Persons skilled in the art will recognize that many alternate refrigeration means exist. Examples include but are not limited to: 1) expansion of a portion of the air component vapor stream 101 to the higher-pressure column 103, 2) expansion of a portion of the air component vapor stream 101 to the lower-pressure column 121, 3) expansion of a portion of the secondary air component vapor stream 151 to the supplemental column 149, and 4) expansion of a vapor from columns 103, 121, and 149, such as a portion of a nitrogen product.

[0040] It will be understood by persons skilled in the art that other processing steps may exist before e.g. any pressure reduction or change. For example, it is common practice to cool liquid streams prior to their introduction to the lower-pressure column 121. Warming cold returning vapor streams, such as waste stream 131, provides this cooling.

[0041] The reflux, or top feed, for the lower-pressure column 121 is shown as stream 139. Other optional reflux streams exist. Examples include but are not limited to: 1) a liquid from an intermediate location of the higher-pressure column 103; and 2) a portion of liquid stream 407 liquid from the top of the supplemental column 149. In such an event, stream 139 may or may not be optionally required.

[0042] It will be understood by persons skilled in the art that other processing steps may exist before any stream is fed to a column. For example, there may be multiple processing steps such as sending a first nitrogen-enriched stream to the higher-pressure column, withdrawing a second nitrogen-enriched stream from the higher-pressure column, and sending the second nitrogen-enriched stream to the supplemental column. The second nitrogen-enriched stream may be withdrawn from the higher-pressure column at the same stage where the first nitrogen-enriched stream is fed to that column or at multiple stages above or below that feed location.

EXAMPLE

[0043] In the following example of the invention, as shown in Figure 6, stream 153 is sent to the bottom of the higher-pressure column 103. Further, only a single enriched nitrogen product is produced, stream 155, at a pressure of 302 psia (2080 kPa). Flows and conditions for major streams can be found in Table 1.

[0044] In comparison, an example for the prior art, as shown in Figure 7, is discussed below. Once more a single nitrogen product, now stream 109, is produced. Again, the pressure of this stream is 302 psia (2080 kPa). Flows and conditions for major streams in this example of the prior art can be found in Table 2.

[0045] It can be seen that the prior art requires higher column pressures in the distillation unit than does the invention. Since higher-pressure columns tend to require thicker, more costly materials, the invention allows for a reduction of the costs involved with the distillation unit. Further, less feed air is required in the invention. Primarily, a large portion of the feed air, 67.5%, does not pass through the higher-pressure column 103; instead, it is sent directly to the supplemental column 149. Secondly, the prior art is able to extract about 63% of the nitrogen entering as feed air, while the invention is able to extract about 75%. The air fed to the higher-pressure column 103 is of a much lower flow and a lower pressure.

[0046] Although illustrated and described herein with reference to certain specific embodiments, the present invention is nevertheless not intended to be limited to the details shown. Rather, various modifications may be made in the details within the scope of the following claims.

Claims

1. A process for separating a multi-component fluid comprising oxygen and nitrogen to produce nitrogen, said process using a distillation column system having at least three distillation columns, including a higher-pressure column operating at a first pressure, a lower-pressure column operating at a second pressure lower than the first pressure, and a supplemental column operating at a third pressure greater than or equal to the second pressure, optionally wherein the higher-pressure column and the lower-pressure column are thermally linked through a first heat exchanger, comprising: